Encrypted communication device, encrypted communication system, encrypted communication method, and program

ABSTRACT

An encrypted communication is correctly decrypted even when key exchange completion notification is delayed. A key storage (10) stores at least one common key which is shared with another encrypted communication device. A key selecting unit (11) selects an encryption key from the at least one common key stored in the key storage (10). An encrypting unit (12) generates encrypted data by encrypting, by using the encryption key, data to be transmitted to the other encrypted communication device. A transmitting unit (13) transmits, to the other encrypted communication device, the encrypted data with a key index, by which the encryption key is uniquely identified, added thereto. A receiving unit (14) receives the encrypted data with the key index added thereto from the other encrypted communication device. A key obtaining unit (15) obtains, from the at least one common key stored in the key storage (10), a decryption key corresponding to the key index added to the encrypted data. A decrypting unit (16) decrypts the encrypted data by using the decryption key.

TECHNICAL FIELD

The present invention relates to information communication technologiesand, in particular, relates to a technology of synchronizing the timingto use a common key in encrypted communication.

BACKGROUND ART

In encrypted communication such as Session Description Protocol (SDP),Real-time Transport Protocol (RTP), and Transport Layer Security (TLS),a common key which is used for encryption is made usable immediatelyafter the transmission or reception of an ACK message or a Finishedmessage (hereinafter referred to as “key exchange completionnotification”) indicating the completion of a key exchange. The detailsof SDP are described in Non-patent Literature 1, the details of RTP aredescribed in Non-patent Literature 2, and the details of TLS aredescribed in Non-patent Literature 3.

For example, in encryption in an IP telephony system, by a multipartykey exchange technique, a Voice over Internet Protocol (VoIP) layer isnotified of the completion of a key exchange as the return value of aterminal API in order to assure the completion of a key exchange betweenterminals which carry out communication. This makes it possible toreproduce a speech sound without interruption of a call even when keysare exchanged at high frequency in one VoIP session.

PRIOR ART LITERATURE Non-Patent Literature

-   Non-patent Literature 1: “Session Description Protocol (SDP)”,    [online], [searched on Jul. 18, 2017], the Internet <URL:    https://tools.ietf.org/html/rfc4568>-   Non-patent Literature 2: “ZRTP: Media Path Key Agreement for Unicast    Secure RTP”, [online], [searched on Jul. 18, 2017], the Internet    <URL: https://tools.ietf.org/html/rfc6189>-   Non-patent Literature 3: “The Transport Layer Security (TLS)    Protocol”, [online], [searched on Jul. 18, 2017], the Internet <URL:    https://tools.ietf.org/html/rfc5246>

SUMMARY OF THE INVENTION Problems to be Solved by the Invention

However, in a best-effort network, an adequate communication band for alower layer cannot be provided due to priority control or the like,which sometimes makes an encrypted communication arrive before keyexchange completion notification. In this case, in spite of the factthat an exchange of a common key is completed, the common key cannot beused, which makes it impossible to decrypt the encrypted communicationcorrectly. For instance, when a mobile virtual network operator (MVNO)network whose communication band is less than 100 kbps is used in amobile network, it has been shown that a reception timing of keyexchange completion notification, which is returned to each terminalfrom a server, is deviated in some terminals, which causes a phenomenonin which speech cannot be correctly decrypted temporarily.

In light of the foregoing, an object of the present invention is toimplement an encrypted communication technology that can correctlydecrypt an encrypted communication even when key exchange completionnotification is delayed.

Means to Solve the Problems

In order to solve the above-described problem, an encryptedcommunication device of the present invention includes: a key storagethat stores at least one common key which is shared with anotherencrypted communication device; a key selecting unit that selects anencryption key from the at least one common key stored in the keystorage; an encrypting unit that generates encrypted data by encrypting,by using the encryption key, data to be transmitted to the otherencrypted communication device; a transmitting unit that transmits, tothe other encrypted communication device, the encrypted data with a keyindex, by which the encryption key is uniquely identified, addedthereto; a receiving unit that receives the encrypted data with the keyindex added thereto from the other encrypted communication device; a keyobtaining unit that obtains, from the at least one common key stored inthe key storage, a decryption key corresponding to the key index addedto the encrypted data; and a decrypting unit that decrypts the encrypteddata by using the decryption key.

Effects of the Invention

With the encrypted communication technology of the present invention, itis possible to decrypt an encrypted communication correctly even whenkey exchange completion notification is delayed.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram for explaining an existing encrypted communicationtechnology.

FIG. 2 is a diagram for explaining an encrypted communication technologyof the present invention.

FIG. 3 is a diagram illustrating the functional configuration of anencrypted communication system.

FIG. 4 is a diagram illustrating the functional configuration of anencrypted communication device.

FIG. 5 is a diagram illustrating a procedure of an encryptedcommunication method.

DETAILED DESCRIPTION OF THE EMBODIMENTS

FIG. 1 shows how a common key is used in an existing encryptedcommunication technology. An example of FIG. 1 illustrates a situationin which a key A and a key B were exchanged between two encryptedcommunication devices and, while key exchange completion notificationfor the key A has been received, key exchange completion notificationfor the key B has not been received. If an encrypted communicationdevice on the transmitting side performs encryption by using the key Bin this situation, an encrypted communication device on the receivingside cannot correctly decrypt an encrypted communication because theencrypted communication device cannot use the key B.

In the present invention, at the time of transmission of an encryptedcommunication, a key index, by which a common key used for encryption isuniquely identified, is added to encrypted data and transmittedtherewith and, at the time of reception of the encrypted communication,a common key corresponding to the key index is obtained and the receivedencrypted data is decrypted. FIG. 2 shows how a common key is used in anencrypted communication technology of the present invention. In anexample of FIG. 2, an encrypted communication device has a key databaseof a common key and a key index which are correlated with each other,and an encrypted communication device on the transmitting side transmitsa key index (=2) corresponding to a key B used for encryption to anencrypted communication device on the receiving side. Although theencrypted communication device on the receiving side has not yetreceived key exchange completion notification for the key B, theencrypted communication device on the receiving side can correctlydecrypt the encrypted data by using the key B because the encryptedcommunication device can obtain the key B from the key database by usingthe key index as a key.

The example of FIG. 2 is based on the assumption that creating thedatabase is performed by sharing a key index with the same timing as akey exchange; however, the example is not limited to this mode because akey index only has to be a key index by which a common key can beuniquely identified. For instance, a configuration may be adopted inwhich a one-way function which is shared between an encryptedcommunication device on the transmitting side and an encryptedcommunication device on the receiving side is provided; at the time oftransmission, an output which is obtained when a common key used forencryption is input to the one-way function is added to encrypted dataas a key index and transmitted therewith and, at the time of reception,a common key is obtained, the common key by which an output, which isequal to the received key index, is obtained when the common key held byan encrypted communication device is input to the one-way function, andthe encrypted data is decrypted. When a key exchange is performedbetween two encrypted communication devices, one encrypted communicationdevice generates a key index and transmits the key index to the otherencrypted communication device, whereby the encrypted communicationdevices can share the key index. When a key management server, which isdifferent from an encrypted communication device, generates a common keyand distributes the common key to encrypted communication devices toperform a key exchange, the key management server generates a key indexand distributes the key index to the encrypted communication deviceswith the common key, whereby the encrypted communication devices canshare the key index.

Hereinafter, embodiments of the present invention will be described indetail. In the drawings, constituent units having the same function areidentified with the same reference character, and overlappingexplanations will be omitted.

First Embodiment

As illustrated in FIG. 3, an encrypted communication system of a firstembodiment includes a plurality of encrypted communication devices 1.

FIG. 3 shows an example in which two encrypted communication devices 1 ₁and 1 ₂ are present; the number of encrypted communication devices 1 isnot limited as long as two or more encrypted communication devices 1 arepresent. In the following description, it is assumed that the encryptedcommunication device 1 ₁ encrypts data and transmits the encrypted dataand the encrypted communication device 1 ₂ decrypts the receivedencrypted data. In this embodiment, the encrypted communication device 1₁ and the encrypted communication device 1 ₂ are connected to acommunication network 2. The communication network 2 is a circuitswitching or packet-switching communication network that allows devicesconnected thereto to communicate with each other on a one-to-one basis,and, for example, the Internet, a local area network (LAN), a wide areanetwork (WAN), or the like can be used. The devices do not necessarilyhave to be able to communicate with each other online via thecommunication network 2. For instance, a configuration may be adopted inwhich information which is output from the encrypted communicationdevice 1 ₁ is stored in a portable recording medium such as a magnetictape or Universal Serial Bus (USB) memory and the information is inputto the encrypted communication device 1 ₂ from the portable recordingmedium offline.

As illustrated in FIG. 4, the encrypted communication device 1 _(i)(i=1, 2) included in the encrypted communication system includes a keystorage 10 _(i), a key selecting unit 11 _(i), an encrypting unit 12_(i), a transmitting unit 13 _(i), a receiving unit 14 _(i), a keyobtaining unit 15 _(i), and a decrypting unit 16 _(i). As a result ofthe two encrypted communication devices 1 ₁ and 1 ₂ performingprocessing in steps shown in FIG. 5 in cooperation with each other, anencrypted communication method of the first embodiment is implemented.

The encrypted communication device 1 _(i) is a special device configuredas a result of a special program being read into a publicly known ordedicated computer including, for example, a central processing unit(CPU), a main storage unit (random access memory: RAM), and so forth.The encrypted communication device 1 _(i) executes each processing underthe control of the central processing unit, for example. The data inputto the encrypted communication device 1 and the data obtained by eachprocessing are stored in the main storage unit, for instance, and thedata stored in the main storage unit is read into the central processingunit when necessary and used for other processing. At least part of eachprocessing unit of the encrypted communication device 1 _(i) may beconfigured with hardware such as an integrated circuit. Each storage ofthe encrypted communication device 1 _(i) can be configured with, forexample, a main storage unit such as random access memory (RAM), anauxiliary storage unit configured with a hard disk, an optical disk, ora semiconductor memory device such as flash memory, or middleware suchas a relational database or a key-value store.

Hereinafter, the encrypted communication method which is executed by theencrypted communication system of the first embodiment will be describedwith reference to FIG. 5.

In the key storage 10 ₁ of the encrypted communication device 1 ₁ on thetransmitting side, at least one common key, which is shared with theencrypted communication device 1 ₂ on the receiving side, and a keyindex, by which each common key is uniquely identified, are stored in astate in which they are correlated with each other. In the key storage10 ₂ of the encrypted communication device 1 ₂ on the receiving side,the at least one common key, which is shared with the encryptedcommunication device 1 ₁ on the transmitting side, and the key index, bywhich each common key is uniquely identified, are stored in a state inwhich they are correlated with each other. Here, “each common key isuniquely identified” means that each common key can be uniquelyidentified in the entire encrypted communication system, not that eachcommon key is uniquely identified in each key storage 10 _(i). That is,when a key index of a common key A which is stored in the key storage 10₁ is 1 and a key index of a common key B which is stored therein is 2, akey index of the common key A which is stored in the key storage 10 ₂ isalso 1 and a key index of the common key B which is stored therein isalso 2. When the encrypted communication device 1 _(i) (i=1, 2)communicates also with the other encrypted communication device 1 _(j)(j=1, 2 and i≠j), for each encrypted communication device 1 _(j) withwhich the encrypted communication device 1 _(i) communicates, theencrypted communication device 1 _(i) only has to store at least onecommon key, which is shared with the encrypted communication device 1_(j), and a key index, by which each common key is uniquely identified,in a state in which they are correlated with each other. As a method bywhich the encrypted communication device 1 ₁ and the encryptedcommunication device 1 ₂ share a common key, an existing key exchangetechnology can be used.

In Step S11, the key selecting unit 11 ₁ of the encrypted communicationdevice 1 ₁ selects one common key which is used for encryption from theat least one common key stored in the key storage 10 ₁ and obtains theselected common key and a key index correlated with the common key fromthe key storage 10 ₁. Hereinafter, the selected common key is referredto as the “encryption key”. In this case, the key selecting unit 11 ₁may select a common key, for which key exchange completion notificationhas not been received, of the at least one common key stored in the keystorage 10 ₁. The key selecting unit 11 ₁ outputs a set made up of theselected encryption key and the key index to the encrypting unit 12 ₁.

In Step S12, the encrypting unit 12 ₁ of the encrypted communicationdevice 1 ₁ receives the set made up of the encryption key and the keyindex from the key selecting unit 11 ₁ and encrypts data to betransmitted to the encrypted communication device 1 ₂ by using theencryption key. As an encryption scheme which is used by the encryptingunit 12 ₁, an existing encryption scheme defined by a communicationprotocol corresponding to data to be transmitted can be used.Hereinafter, the data which is encrypted is referred to as the“encrypted data”. The encrypting unit 12 ₁ outputs a set made up of thegenerated encrypted data and the key index to the transmitting unit 13₁.

In Step S13, the transmitting unit 13 ₁ of the encrypted communicationdevice 1 ₁ receives the set made up of the encrypted data and the keyindex from the encrypting unit 12 ₁ and transmits the encrypted datawith the key index added thereto to the encrypted communication device 1₂.

In Step S14, the receiving unit 14 ₂ of the encrypted communicationdevice 1 ₂ receives the encrypted data with the key index added theretofrom the encrypted communication device 1 ₁. This key index is a keyindex corresponding to the encryption key used when the encrypted datawas encrypted and is a key index corresponding to any one of the atleast one common key stored in the key storage 10 ₂ of the encryptedcommunication device 1 ₂. The receiving unit 14 ₂ outputs the receivedkey index to the key obtaining unit 15 ₂ and outputs the receivedencrypted data to the decrypting unit 16 ₂.

In Step S15, the key obtaining unit 15 ₂ of the encrypted communicationdevice 1 ₂ receives the key index from the receiving unit 14 ₂ andretrieves and obtains a common key correlated with the key index fromthe key storage 10 ₂ of the encrypted communication device 1 ₂.Hereinafter, the obtained common key is referred to as the “decryptionkey”. It goes without saying that, since the encryption key and thedecryption key are correlated with the same key index, they are one andthe same common key. The key obtaining unit 15 ₂ outputs the obtaineddecryption key to the decrypting unit 16 ₂.

In Step S16, the decrypting unit 16 ₂ of the encrypted communicationdevice 1 ₂ receives the decryption key from the key obtaining unit 15 ₂and decrypts the encrypted data received from the receiving unit 14 ₂ byusing the decryption key. A decryption scheme which is used by thedecrypting unit 16 ₂ is a decryption scheme corresponding to theencryption scheme used by the encrypting unit 12 ₁.

As a result of the encrypted communication system of the firstembodiment being configured as described above, the encryptedcommunication system transmits encrypted data with a key index, whichcorresponds to a common key used for encryption, added thereto, whichmakes it possible to use even a common key, for which key exchangecompletion notification has not been received, for encryption anddecryption if a key exchange itself is completed. Thus, even when keyexchange completion notification is delayed due to the influence of, forexample, priority control of a network or the like and encrypted dataarrives before the key exchange completion notification, the encrypteddata can be correctly decrypted.

Second Embodiment

In the first embodiment, a configuration in which a key index, by whicheach common key is uniquely identified, is stored in advance in the keystorage 10 _(i) in a state in which a key index is correlated with eachcommon key has been described. In an encrypted communication system of asecond embodiment, a configuration is adopted in which a key index isgenerated as occasion arises by using a one-way function which is sharedbetween encrypted communication devices. Hereinafter, a differencebetween the encrypted communication system of the second embodiment andthe encrypted communication system of the first embodiment will bemainly described.

In the key storage 10 ₁ of the encrypted communication device 1 ₁ of thesecond embodiment, at least one common key, which is shared with theencrypted communication device 1 ₂ on the receiving side, and a one-wayfunction, which is shared with the encrypted communication device 1 ₂ ofthe second embodiment, are stored. In the key storage 10 ₂ of theencrypted communication device 1 ₂ of the second embodiment, at leastone common key, which is shared with the encrypted communication device1 ₁ on the transmitting side, and the one-way function, which is sharedwith the encrypted communication device 1 ₁ of the second embodiment,are stored. As this one-way function, a hash function such as SHA-256can be used.

In Step S11, the key selecting unit 11 ₁ of the encrypted communicationdevice 1 ₁ selects one encryption key which is used for encryption fromthe at least one common key stored in the key storage 10 ₁ and obtainsthe selected encryption key from the key storage 10 ₁. Moreover, the keyselecting unit 11 ₁ generates an output which is obtained when theobtained encryption key is input to the one-way function stored in thekey storage 10 ₁ as a key index. The key selecting unit 11 ₁ outputs aset made up of the selected encryption key and the key index to theencrypting unit 12 ₁.

The processing from Steps S12 to S14 is the same as that of the firstembodiment.

In Step S15, the key obtaining unit 15 ₂ of the encrypted communicationdevice 1 ₂ receives the key index from the receiving unit 14 ₂ andobtains a common key by which an output, which is equal to the receivedkey index, is obtained when the common key stored in the key storage 10₂ is input to the one-way function stored in the key storage 10 ₂ as adecryption key. The key obtaining unit 15 ₂ outputs the obtaineddecryption key to the decrypting unit 16 ₂.

The processing in Step S16 is the same as that of the first embodiment.

As a result of the encrypted communication system of the secondembodiment being configured as described above, although the amount ofcomputation needed to calculate a key index every time an encryption keyis selected and every time a decryption key is obtained is increased,there is no need to store a key index in advance in the encryptedcommunication devices in such a way that the key index is sharedtherebetween, which eliminates the need for key index sharing processingat the time of a key exchange and makes it possible to reduce thecapacity of the key storage 10 _(i) of the encrypted communicationdevice 1 _(i).

While the embodiments of the present invention have been described,specific configurations are not limited to these embodiments, but designmodifications and the like within a range not departing from the spiritof the invention are encompassed in the scope of the invention, ofcourse. The various processes described in the embodiments may beexecuted in parallel or separately depending on the processing abilityof a device executing the process or on any necessity, rather than beingexecuted in time series in accordance with the described order.

[Program and Recording Medium]

When various types of processing functions in the devices described inthe above embodiments are implemented on a computer, the contents ofprocessing function to be contained in each device is written by aprogram. With this program executed on the computer, various types ofprocessing functions in the above-described devices are implemented onthe computer.

This program in which the contents of processing are written can berecorded in a computer-readable recording medium. The computer-readablerecording medium may be any medium such as a magnetic recording device,an optical disk, a magneto-optical recording medium, and a semiconductormemory.

Distribution of this program is implemented by sales, transfer, rental,and other transactions of a portable recording medium such as a DVD anda CD-ROM on which the program is recorded, for example. Furthermore,this program may be stored in a storage unit of a server computer andtransferred from the server computer to other computers via a network soas to be distributed.

A computer which executes such program first stores the program recordedin a portable recording medium or transferred from a server computeronce in a storage unit thereof, for example. When the processing isperformed, the computer reads out the program stored in the storage unitthereof and performs processing in accordance with the program thus readout. As another execution form of this program, the computer maydirectly read out the program from a portable recording medium andperform processing in accordance with the program. Furthermore, eachtime the program is transferred to the computer from the servercomputer, the computer may sequentially perform processing in accordancewith the received program. Alternatively, a configuration may be adoptedin which the transfer of a program to the computer from the servercomputer is not performed and the above-described processing is executedby so-called application service provider (ASP)-type service by whichthe processing functions are implemented only by an instruction forexecution thereof and result acquisition. It should be noted that aprogram according to the present embodiment includes information whichis provided for processing performed by electronic calculation equipmentand which is equivalent to a program (such as data which is not a directinstruction to the computer but has a property specifying the processingperformed by the computer).

In the present embodiment, the present device is configured with apredetermined program executed on a computer. However, the presentdevice may be configured with at least part of these processing contentsrealized in a hardware manner.

1. An encrypted communication device comprising: a key storage thatstores at least one common key which is shared with another encryptedcommunication device; and processing circuitry configured to: select anencryption key from the at least one common key stored in the keystorage; generate encrypted data by encrypting, by using the encryptionkey, data to be transmitted to the other encrypted communication device;transmit, to the other encrypted communication device, the encrypteddata with a key index, by which the encryption key is uniquelyidentified, added thereto; receive the encrypted data with the key indexadded thereto from the other encrypted communication device; obtain,from the at least one common key stored in the key storage, a decryptionkey corresponding to the key index added to the encrypted data; anddecrypt the encrypted data by using the decryption key.
 2. The encryptedcommunication device according to claim 1, wherein the key storagestores a key index, by which each common key is uniquely identified, ina state in which the key index is correlated with each common key, theprocessing circuitry selects the encryption key from the at least onecommon key stored in the key storage and obtains the key indexcorrelated with the encryption key, and the processing circuitryobtains, as the decryption key, the common key correlated with a samekey index as the key index added to the encrypted data from the at leastone common key stored in the key storage.
 3. The encrypted communicationdevice according to claim 1, wherein the processing circuitry selectsthe encryption key from the at least one common key stored in the keystorage and obtains, as the key index, an output which is obtained whenthe encryption key is input to a one-way function, and the processingcircuitry obtains, as the decryption key, the common key by which anoutput, which is equal to the key index added to the encrypted data, isobtained when the common key stored in the key storage is input to theone-way function.
 4. An encrypted communication system in which aplurality of encrypted communication devices transmit and receiveencrypted data, wherein each encrypted communication device includes akey storage that stores at least one common key which is shared withanother encrypted communication device, and processing circuitryconfigured to: select an encryption key from the at least one common keystored in the key storage, generate the encrypted data by encrypting, byusing the encryption key, data to be transmitted to the other encryptedcommunication device, transmit, to the other encrypted communicationdevice, the encrypted data with a key index, by which the encryption keyis uniquely identified, added thereto, receive the encrypted data withthe key index added thereto from the other encrypted communicationdevice, obtain, from the at least one common key stored in the keystorage, a decryption key corresponding to the key index added to theencrypted data, and decrypt the encrypted data by using the decryptionkey.
 5. An encrypted communication method by which a first encryptedcommunication device and a second encrypted communication devicetransmit and receive encrypted data, wherein the first encryptedcommunication device stores at least one common key, which is sharedwith the second encrypted communication device, in a first key storage,the encrypted communication method comprising: storing, by the secondencrypted communication device, the at least one common key, which isshared with the first encrypted communication device, in a second keystorage, selecting, by the first encrypted communication device, anencryption key from the at least one common key stored in the first keystorage, generating, by the first encrypted communication device, theencrypted data by encrypting, by using the encryption key, data to betransmitted to the second encrypted communication device, transmitting,by the first encrypted communication device, to the second encryptedcommunication device, the encrypted data with a key index, by which theencryption key is uniquely identified, added thereto, receiving, by thesecond encrypted communication device, the encrypted data with the keyindex added thereto from the first encrypted communication device,obtaining, by the second encrypted communication device, from the atleast one common key stored in the second key storage, a decryption keycorresponding to the key index added to the encrypted data, anddecrypting by the second encrypted communication device, the encrypteddata by using the decryption key.
 6. A program for making a computerfunction as the encrypted communication device according to any one ofclaims 1 to 3.